Next Article in Journal
Spotlight on New Hallmarks of Drug-Resistance towards Personalized Care for Epithelial Ovarian Cancer
Previous Article in Journal
The Role of Cardiolipin in Mitochondrial Function and Neurodegenerative Diseases
Previous Article in Special Issue
Suggesting Dictyostelium as a Model for Disease-Related Protein Studies through Myosin II Polymerization Pathway
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Cells
Volume 13
Issue 7
10.3390/cells13070610
cells-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Polycystin-2 Mediated Calcium Signalling in the Dictyostelium Model for Autosomal Dominant Polycystic Kidney Disease

by
Claire Y. Allan
,
Oana Sanislav
and
Paul R. Fisher
*
Department of Microbiology, Anatomy, Physiology and Pharmacology, La Trobe University, Bundoora, Melbourne, VIC 3086, Australia
*
Author to whom correspondence should be addressed.
Cells 2024, 13(7), 610; https://0-doi-org.brum.beds.ac.uk/10.3390/cells13070610
Submission received: 8 February 2024 / Revised: 26 March 2024 / Accepted: 27 March 2024 / Published: 31 March 2024
(This article belongs to the Special Issue Simple Organisms for Complex Problems: Modeling Human Disease in Yeast and Dictyostelium II)
Browse Figures
Review Reports Versions Notes

Abstract

:
Autosomal dominant polycystic kidney disease (ADPKD) occurs when the proteins Polycystin-1 (PC1, PKD1) and Polycystin-2 (PC2, PKD2) contain mutations. PC1 is a large membrane receptor that can interact and form a complex with the calcium-permeable cation channel PC2. This complex localizes to the plasma membrane, primary cilia and ER. Dysregulated calcium signalling and consequential alterations in downstream signalling pathways in ADPKD are linked to cyst formation and expansion; however, it is not completely understood how PC1 and PC2 regulate calcium signalling. We have studied Polycystin-2 mediated calcium signalling in the model organism Dictyostelium discoideum by overexpressing and knocking down the expression of the endogenous Polycystin-2 homologue, Polycystin-2. Chemoattractant-stimulated cytosolic calcium response magnitudes increased and decreased in overexpression and knockdown strains, respectively, and analysis of the response kinetics indicates that Polycystin-2 is a significant contributor to the control of Ca2+ responses. Furthermore, basal cytosolic calcium levels were reduced in Polycystin-2 knockdown transformants. These alterations in Ca2+ signalling also impacted other downstream Ca2+-sensitive processes including growth rates, endocytosis, stalk cell differentiation and spore viability, indicating that Dictyostelium is a useful model to study Polycystin-2 mediated calcium signalling.

1. Introduction

Autosomal dominant polycystic kidney disease (ADPKD) is a very frequently occurring renal disease in which people suffer from enlarged renal and hepatic cysts and can often be fatal. Mutations in the genes PKD1 and PKD2 encoding the two key proteins, polycystin-1 (PC1) and Polycystin-2 (PC2) respectively, are associated with the disease [1], with most cases (over 85%) linked to PC1 mutations; however, mutations in PC2 also contribute to disease pathology [1,2]. PC2 belongs to the transient receptor potential (TRP) channel superfamily of membrane-embedded ion-conducting channels. TRPs are involved in many cellular processes and are increasingly being investigated for their potential as therapeutic drug targets [3]. In mammals, PC2 is localized to various cellular structures, which include the primary cilium, plasma membrane and endoplasmic reticulum (ER) [4,5,6,7,8,9]. Its role as a mediator of intracellular and extracellular calcium release positions PC2 as a key player in sensory signalling [4,9]. PC2 forms complexes with PC1, an integral membrane mechanosensitive receptor situated in the primary cilium [10]. When subjected to fluid stress, PC1 triggers calcium influx into the cytoplasm through PC2 [6]. This calcium signal is further augmented by the release of calcium from the ER via PC2, thereby governing calcium-dependent signalling processes [6,11,12]. Moreover, PC2 interacts with other intracellular calcium channels, such as the Inositol trisphosphate receptor (InsP3R) of the ER and the ryanodine receptor of the sarcoplasmic reticulum, to regulate calcium signalling [13,14,15]. ADPKD cells exhibit reduced intracellular calcium concentrations, which are believed to be associated with elevated levels of cyclic adenosine monophosphate (cAMP). This dysregulation leads to fluid secretion, activation of MAPK/ERK signalling pathways and subsequent cell proliferation [16]. Ultimately, these disrupted processes result in uncontrolled cell proliferation and the development of fluid-filled cysts [17,18,19]. Cyst formation and progression involve oxidative stress [20,21], inflammation and cell death [22,23]; however, the mechanisms behind cyst development are still poorly understood.
Extensive research has been conducted on PC2 in various cellular models [24], including Caenorhabditis elegans [25], Drosophila [26,27] and mice [28]. Additionally, a PC2 homologue called Polycystin-2 [29], also known as PKD2 [30], TrpP [31] or Trpp2 [32], has been identified in the model organism Dictyostelium discoideum [29]. The Dictyostelium Polycystin-2 protein (gene name pkd2 or TrpP) has been the subject of a small number of studies that have only just begun to understand its function. The utilization of Dictyostelium as a model organism for studying ADPKD has been demonstrated in a compelling study in which the antiproliferative drug Naringenin was screened using Dictyostelium mutants to assess its impact on cell growth. Remarkably, Naringenin exhibited growth restriction specifically dependent on Polycystin-2, and the study further demonstrated that this growth inhibition also reduced the progression of cyst development in Madin–Darby canine kidney (MDCK) tubule cells in a collagen matrix [33]. These findings emphasize the potential of Dictyostelium in investigating ADPKD and highlight the critical need to deepen our understanding of protein function in this organism, especially in relation to its calcium regulatory properties.
Dictyostelium is a simple and tractable model that is ideal for studying protein function and the molecular mechanisms underpinning disease pathogenesis. It presents an excellent opportunity to explore the molecular functions of Polycystin-2 further. Dictyostelium Polycystin-2, which shares 46% protein similarity with human PC2, is predicted to have six transmembrane domains, a conserved pore region between TM 5 and 6 and a conserved C-terminal coiled-coil domain [30]. Unlike mammalian PC2, Polycystin-2 lacks the EF-hand motif and ER retention signal [29]. Immunolocalization studies with FLAG-tagged Polycystin-2 show its presence mainly at the plasma membrane, where it colocalizes with the marker H-36, and also some colocalization with recycling and early endocytic compartments [30]. Additionally, Polycystin-2 had been confirmed to be localized at the plasma membrane and some cytoplasmic puncta as visualized using a GFP fusion protein [31] and with an anti-Polycystin-2 antibody [34]. The role of Polycystin-2 in Dictyostelium appears to be associated with calcium regulation. Polycystin-2 knockout strains exhibit defects in Ca2+-induced lysosomal exocytosis, indicating its involvement in cytosolic calcium release, which regulates this process [30]. Additionally, Polycystin-2 may be associated with calcium signalling related to rheotaxis [30], although the reproducibility of this phenotype has been questioned [31,35]. Polycystin-2 knockout strains show impaired cytosolic calcium influx in response to ATP and ADP, while still retaining responses to cAMP and folic acid [31]. The regulatory mechanisms and potential interactions of Polycystin-2, such as its interaction with the putative PC1 homologue encoded in the Dictyostelium genome (dictyBase gene ID: DDB_G0289409), remain unknown and require further investigation. Clearly, additional studies are necessary to elucidate the role of Polycystin-2 in calcium signalling and its mode of action.
Here we have conducted a comprehensive analysis of the role of Polycystin-2 by examining phenotypic readouts in strains overexpressing the protein, or in knockdown strains (KD) with reduced levels of the protein resulting from antisense RNA inhibition (asRNA). The focus was on characterizing the contribution of Polycystin-2 to chemotactic calcium signalling in responses to the stimuli cAMP (in aggregation-competent cells) and folic acid (in vegetative, growth-phase cells). The use of knockdown and overexpression systems allowed us to correlate phenotypic readouts with the copy number of the constructs. This approach involved multiple, independently isolated mutant strains with different numbers of copies of the knockdown and overexpression constructs. It enables regression analysis of phenotype versus copy number and reduces the likelihood of unknown off-target genetic events influencing the outcomes. Consequently, this approach increased the sensitivity to detect even subtle phenotypic abnormalities that may not be apparent in the analysis of KO strains. The results show that overexpression of Polycystin-2 enhances cytosolic calcium responses to both cAMP and folic acid while knockdown reduces these responses, implicating Polycystin-2-dependent calcium fluxes in contributing to these responses. These alterations in calcium signalling also have downstream effects on other calcium-sensitive processes, including growth, endocytosis, cell differentiation and spore viability.

2. Materials and Methods

2.1. Gene Cloning and Sequence Analysis

Vector construction and cloning procedures were conducted as described previously [36,37]. Gene fragments for cloning were amplified using gene-specific primers incorporating restriction enzyme cut sites at the 5′end to facilitate cloning. The 2717 bp Dictyostelium homologue of Polycystin-2 (pkd2), identified by Wilczynska et al., (2005) [29] (dictyBase gene ID. DDB_G0272999), was amplified in two sections from AX2 genomic DNA with primers POLYF 5′-CGCGGATCCATCGATATGAATACATTAAAGAGGACAGT-3′ and PolyMR 5′-CATATATAATTGAATTCTATAAGTTC-3′ for the 5′ section and PolyMF 5′-GAACTTATAGAATTCAATTATATATG-3′ and POLYR 5′-CGCGGATCCCTCGAG TTAAGGTGTATTAGTACCACCA-3′ for the 3′ section. The full-length gDNA was cloned in two sections into the bacterial vector pZErO-2 (Invitrogen, Carlsbad, CA, USA) using the restriction sites indicated by underlining and utilization of a resident EcoR1 restriction site (indicated by italics) within the gene sequence, which facilitated seamless ligation of the 5′ and 3′ gene fragments (pPROF635). The gene was then subcloned for overexpression into the vector pA15GFP, replacing the resident green fluorescent protein gene (pPROF636). Plasmid constructs for expression of pkd2 antisense RNA were created by amplifying a 787bp fragment of the gene, via reverse transcription-PCR with the primers POLYF and PolyMR. Template RNA was extracted from vegetative AX2 cells with TRIzol® (Invitrogen). The gene products were then cloned into pZErO™-2 and subcloned in the antisense orientation into the Dictyostelium expression vector pDNeo2 (pPROF646).
Sequencing was conducted by The Australian Genome Research Facility (AGRF) (http://www.agrf.org.au). Sequences we analysed using the software Basic Local Alignment Search Tool (BLAST) version 2.2.23 (National Center for Biotechnology Information (NCBI), Bethesda, MD, USA, accessed on 12 February 2009), and ClustalW version 2 (European Molecular Biology Laboratory—European Bioinformatics Institute, Cambridge, UK, accessed on 6 August 2009). These software were accessed through ExPASy (http://www.expasy.org, SIB Swiss Institute of Bioinformatics, Lausanne, Switzerland). Database searches were performed through dictyBase (http://www.dictybase.org, accessed on 30 August 2005).

2.2. Dictyostelium Transformation

Strains were created by the transformation of the parental strain AX2 as described previously [36,37,38]. Each strain (assigned HPF codes) carried different numbers of copies of the following constructs: (1) pPROF120 and pPROF646 (antisense HPF642-644, HPF831, HPF833, HPF835-837), (2) pPROF120 and pPROF648 (sense HFP838 & HPF848) and (3) pPROF120 and pPROF636 (Overexpression HPF839-841, HFP644-646, HPF651-653). The transformation was carried out via the Ca(PO4)2/DNA coprecipitation method by cotransformation with both plasmids [39]. Isolated single colonies were selected from lawns of Micrococcus luteus grown on Standard Medium (SM) agar containing 25 µg/mL G418 [40].

2.3. Strains and Culture Conditions

Dictyostelium cultures were subsequently maintained on Enterobacter aerogenes lawns prepared on SM agar, and axenically in HL5 medium [41]. To remove any possible effects of the antibiotics on phenotypic outputs, strains were subcultured at least one time into HL5 without antibiotics and grown for 24–48 h prior to use in experiments. Cells were harvested by centrifugation at 500× g for 5 min, unless otherwise stated.

2.4. Estimation of Plasmid Copy Number Using Quantitative Real-Time PCR

The copy number of each plasmid inserted into the genome of the Dictyostelium strains was determined by quantitative real-time PCR (qRT-PCR) as described previously [41]. The primers used were: Polycystin-2 (103 bp amplicon): Forward primer 5′-CGCGGATCCAAGCTTATGAATACATTAAAGAGGACAGT-3′, Reverse primer 5′-CAACTGCTGCCAATAATGTTGC-3′. Filamin (100 bp amplicon of abpC gene): Forward primer 5′-CCCTCAATGATGAAGCC-3′, Reverse primer 5′-CCATCTAAACCTGGACC-3′.

2.5. Quantification of mRNA Expression Levels

Semiquantitative reverse transcription PCR was used to quantitate expression levels of pkd2. RNA was extracted from 107 vegetative cells or cells harvested from water agar every 2 h over 24 h for the developmental time course using TRIzol® (Invitrogen) and treated with RQ1 DNase (Promega, Madison, WI, USA) according to the manufacturer’s instructions. The iScript™ One-Step RT-PCR Kit with SYBR® Green (BioRad, Hercules, CA, USA) was used for amplicon detection using the primers outlined in Section 2.4. An RNA template of 50–100 ng was added to the total reaction mixture of 50 μL; cDNA synthesis was performed at 50 °C for 10 min, and the PCR cycling and detection used 45 cycles of denaturation at 95 °C for 30 s, annealing at 58 °C for 30 s and extension and data collection at 72 °C. Expression was normalized against the abpC mRNA levels to adjust for loading and then measured relative to AX2 controls.

2.6. Plaque Expansion Rates on Bacterial Lawns and Determination of Generation Times of Axenically Growing Cultures

Growth experiments were conducted as described previously [41]. The expansion rates of Dictyostelium plaques on E. coli B2 lawns were assessed by measuring plaque diameter every 8–10 h for 100 h. Generation times of axenic Dictyostelium cultures in HL5 were determined by hemocytometer cell counts at 8–12 h intervals over 72 h. The recorded values were analysed by linear regression using the “R” environment for statistical computing and graphics (http://www.R-project.org, accessed on 28 June 2006) to determine the plaque expansion rate (mm/h) on bacterial lawns, or the generation time (h) from the exponential growth curve in shaken axenic culture.

2.7. Endocytosis Assays

Phagocytosis levels in D. discoideum strains were assessed by quantifying the uptake of an E. coli strain that expressed the fluorescent protein DsRed [42], following the method described previously [41]. Meanwhile, the rates of macropinocytosis were evaluated by measuring the uptake of fluorescein isothiocyanate (FITC)-dextran (Sigma-Aldrich, average molecular weight 70 kDa, St. Louis, MO, USA), also following the procedure described [41].

2.8. Morphology

To observe mature fruiting body morphology, cells were allowed to develop on lawns of Enterobacter as previously described [37]. After 24 h, images were taken using a Moticam 2300 camera attached to an Olympus SZ61 stereomicroscope from above and from the side of an excised piece of agar containing the fruiting body.

2.9. Quantification of LysoSensor™ Blue DND-167 Staining in Cells

Dictyostelium cells were grown in HL5 to a density of 1–3 × 106 cells mL−1 and then 1 × 106 cells were harvested (1500× g for 2 min) and resuspended in 1 mL of Lo-Flo HL5 (3.85 gL−1 glucose, 1.78 gL−1 Proteose peptone, 0.45 gL−1 yeast extract, 0.485 gL−1 KH2PO4 and 1.2 gL−1 Na2HPO4·12H2O; filter sterile). Aliquots of 100 µL of the cell suspension were seeded into 4 wells of a black 96-well microplate. To two wells, 100 µL of Lo-Flo HL5 was added as background controls, and to the other two wells, 100 µL of 1µM LysoSensorTM Blue DND-167 (Invitrogen) was added. The plate was incubated in the dark for 30 min at 21 °C, and the fluorescence was recorded on a CLARIOstar plate reader (Ex.373 Em.425) The background fluorescence of the undyed cells was subtracted from the fluorescence recorded from the Lysosensor Blue™ stained cells.

2.10. Determination of Spore Viability

Dictyostelium strains were grown to a density of 1–2 × 106 cells mL−1 in the HL5 medium. 1 × 107 cells were harvested (500× g for 5 min) and washed 2× in PBS. The cell pellet was resuspended in 50 μL PBS and pipetted in a 1 cm2 area on non-nutrient agar and incubated at 21 °C until fruiting bodies had formed. The fruiting bodies were scraped from the surface using a sterile tip, resuspended in 1 mL PBS and washed 2× in PBS (1000× g 2 min), then resuspended in PBS (0.1% v/v NP40) and incubated at 42 °C for 30 min to kill amoebae and activate spores [43,44]. The spores were washed in 2× in PBS and counted using a hemocytometer. Duplicate plates of 300 and 100 spores were plated onto SM agar by mixing with a thick slurry of E. aerogenes and evenly spread onto the agar. Plates were incubated at 21 °C for ~3 days until spores had germinated and plaques had formed. Each plaque was assumed to have arisen from an individual spore. The number of plaques was counted, and the spore viability was calculated as the percentage of plated spores that produced plaques.

2.11. Calcium Experiments

Expression of the Ca2+ sensitive luminescent protein apoaequorin, in each Dictyostelium, strain was used to measure cytosolic Ca2+ concentration ([Ca2+]c) as described previously [41]. Briefly, axenic cultures in HL5 were grown to 1–2 × 106 cells mL−1, with 1 × 108 cells harvested. Cells were either resuspended in HL5 (2 × 107 cells ml−1) or to initiate aggregation competence washed twice in 20 mL MES-DB (10 mM MES/NaOH, pH 6.2, 10 mM KCl, 0.25 mM CaCl2), and resuspended to 2 × 107 cells ml−1 in MES-DB. Cells were loaded with 5 µM coelenterazine-h (Invitrogen) and incubated at 21 °C and 150 rpm for 4 h (for experiments using vegetative cells) or 6–7 h (for experiments with aggregation competent cells). Determination of the consumption of aequorin and measurements of in vivo Ca2+ concentrations were conducted in a Lumitran® model L-3000 photometer (New Brunswick Scientific, Edison, NJ, U.S.A ). Luminescence signals were recorded from 5 mL cell suspensions stirred at 100 rpm stimulated with chemoattractant (final concentration 1 µM). A model PCI-20428 multifunction I/O data acquisition board (Intelligent Instruments Pty. Ltd., Southampton, Hampshire, England) was used to capture the signal, which was then converted into values of [Ca2+]c on a PC using purpose-designed software developed by (Prof. P. R. Fisher) written in the Intelligent Instruments graphical programming language for the PCI-20428. Subsequent statistical and graphical analyses were performed in the WinStat Excel add-on and in the ‘R’ programming language for data analysis and graphical display.

2.12. Statistical Analysis

Data analysis was conducted using Microsoft Excel and the ‘R’ programming language. Independent t-tests or One-Way ANOVA, with pairwise comparisons made by the Least-Squares Difference method, were used to compare means. Pearson product-moment, Spearman’s rank and Kendall’s rank correlation coefficients were used to determine significant correlations. Regression analysis was performed as indicated in the figure legends.

3. Results

3.1. Developmental Expression of pkd2

Upon starvation, Dictyostelium cells begin a developmental program that involves various stages, leading to multicellular differentiation and ending in the formation of mature fruiting bodies [45]. Gene expression begins to change immediately upon starvation and can vary over the developmental period [46]. To investigate the expression of pkd2 during development, AX2 cells were plated onto water agar and starved for 24 h, during which time RNA samples were harvested every 2 h to capture the different developmental stages. The relative expression of pkd2 was assessed using semiquantitative RT-PCR. pkd2 showed continuous expression throughout development, increasing swiftly to a peak within the initial 2 h of early development in reaction to the initiation of starvation. Subsequently, its expression declined between 2 and 8 h, before experiencing another rise during aggregation, reaching its highest level at 10 h. Throughout multicellular development, expression levels remained elevated (Figure 1A). Our expression data show a similar trend to the RNAseq-derived mRNA expression time course of pkd2 in AX4 developed on KK2 filter paper as determined by Parikh A et al. [47], represented in Figure 1B from data retrieved from dictyexpress.org [48,49]. Our results are also broadly similar to the mRNA developmental time course previously published [31], except in that case, the initial peak at 2 h in expression is higher than that of expression later in development. These differences in detail may be due to differences in the expression assays or in the developmental conditions. Combined, these expression patterns suggest roles for Polycystin-2-dependent calcium signalling during early starvation-induced development, and also during the lifecycle multicellular stages.

3.2. Genetic Manipulation of pkd2 Expression by Transformation of D. discoideum with Plasmid Constructs

Dictyostelium strains were generated by transforming them to express constructs that either suppress mRNA expression through antisense mRNA inhibition- knockdown (KD) strains or enhance mRNA expression–overexpression strains. Plasmid integration takes place randomly in the genome through a process known as recombination and rolling circle replication. The outcome of this process produces individual strains with varying copy numbers of integrated plasmids, resulting in differing levels of mRNA expression [50]. To determine the number of copies integrated into the genome of each transformant, quantitative real-time PCR was used, and semiquantitative real-time RT-PCR was used to determine the subsequent mRNA expression levels. A regression analysis was then carried out to determine any relationship. As anticipated, antisense inhibition led to a reduction in mRNA expression, overexpression increased expression and there was a significant correlation between copy number and mRNA expression (Figure 2). This allowed us to create a pkd2 expression index for phenotypic analysis, following the previously published convention of using negative values (the antisense inhibition construct copy number) and positive values (the overexpression construct copy number) [38]. This allowed gene dose–response relationships to be determined and revealed correlations between the construct copy number and the severity of phenotypes.

3.3. Polycystin-2 Contributes to Chemotactic Calcium Responses in Dictyostelium

To further investigate the role of Polycystin-2 in Ca2+ signalling, we used our Polycystin-2 knockdown and overexpressing strains to measure changes in cytosolic calcium concentrations in vegetative cells stimulated with folic acid, as well as in aggregation-competent cells stimulated with cAMP. Real-time cytosolic Ca2+ responses were measured using these strains, which also expressed a luminescent recombinant Ca2+-sensitive protein, apoaequorin. The cytosolic Ca2+ responses in cells stimulated with folic acid and cAMP were already well-characterized in the parental strain AX2 expressing aequorin (HPF401) [51]. This method provides sensitive and accurate readings with a temporal resolution of 20 ms and is sensitive enough to detect changes in [Ca2+]c of 2 to 3 nM [29]. Representative real-time recordings of [Ca2+]c were measured in three strains—the control strain expressing aequorin (HPF401), the Polycystin-2 knockdown strain (HPF644) and the Polycystin-2 overexpression strain (HPF839)—which are shown in Figure 3. Vegetative cells were stimulated with 1 μM folic acid (Figure 3 upper panel) and optimally starved cells were stimulated with 1 μM cAMP (Figure 3 lower panel). Larger and smaller response magnitudes, compared to control (HPF401), were observed in overexpression and KD strains, respectively, for both folic acid and cAMP stimulation. In vegetative cells, response magnitudes decreased by an average of 45.5% in KD strains and increased by 48% in overexpression strains compared to the control average. In differentiated cells, response magnitudes were decreased by an average of 35.8% in KD strains and increased by 42.8% in overexpression strains compared to the control average. A regression analysis was then conducted to analyse the mean response magnitudes from five different KD strains and five different overexpression strains carrying different plasmid copy numbers. The magnitude of the Ca2+ responses, to both chemoattractants, was positively correlated with the pkd2 expression index (Figure 4A,B). The observation of similar copy number-dependent phenotypes in multiple, independently isolated clonal cell lines excludes the possibility that the altered Ca2+ responses might be due to additional, random and unknown genetic events elsewhere in the genomes of the mutant strains. Interestingly, a previous study reported that Polycystin-2 KO cells still retain their cytosolic calcium responses to folic acid and cAMP measured in single cells expressing a genetically encoded cytoplasmic calcium sensor [31]. This means that Polycystin-2 cannot be the only calcium channel involved in facilitating this calcium influx. However, this does not exclude the possibility that Polycystin-2 contributes to the calcium influx, and our results support its role in contributing to cytosolic Ca2+ release into the cytoplasm.

3.3.1. Analysis of the Kinetics of Ca2+ Responses to Chemoattractant

The kinetics of these chemotactic Ca2+ responses are known to be partly dependent on the response magnitude itself. Larger responses start earlier and peak earlier due to the faster increase in cytosolic Ca2+, and the maximum rise and fall rates of Ca2+ flux into and out of the cytoplasm are correlated [29]. This confirms that the responses are autocatalytic during the rising phase when calcium is entering the cytosol, implying Ca2+-induced Ca2+ entry into the cytosol with more channels opening earlier and allowing more rapid increases in cytosolic Ca2+. The responses are also self-limiting in the falling phase of the response, with larger responses being terminated more quickly because the Ca2+ itself homeostatically activates the mechanisms that clear Ca2+ from the cytoplasm, such as closure of Ca2+ channels or activation of Ca2+ pumps [29].
To explore these relationships further, we measured the maximum rise and fall rates of cytosolic Ca2+ in pkd2 mutants and observed the same relationship in response kinetics to both cAMP and folic acid (Figure 5A). This shows that the Ca2+-regulated Ca2+ channels and pumps are the same for the two attractants since responses to them exhibit the same kinetic properties. We also plotted the relationship between the response onset time and response magnitude. The relationship is negative for Polycystin-2 overexpression, KD and control strains (Figure 5B), and in this respect, is similar to the relationship previously reported for wild-type, calnexin-deficient and calreticulin-deficient strains [29]. Calnexin and calreticulin are avid Ca2+-binding proteins in the endoplasmic reticulum that contribute to the sequestration of Ca2+ in the lumen of the ER. The data for all three of those strains fell onto the same regression line, with the strains differing only in their position on the line. This was in keeping with differences in the steepness of the free Ca2+ gradients resulting from the loss of Ca2-sequestering capacity in the ER. In this present work, however, each set of strains falls on a different line in what appears to be a family of similar log-linear regressions. In overexpression strains, the response magnitude is greater than the controls by a constant amount (regression intercept increased but slope unchanged) at all response times. Conversely, the response magnitude is reduced by a constant amount, independent of response times, compared to controls (the intercept is lower but the slope is unchanged) (Figure 5B). The simplest explanation is that Polycystin-2 is a significant contributor to the Ca2+ responses at all response times and magnitudes, but that its expression levels do not affect the mechanism by which response time and magnitude are coupled, e.g., in the form of Ca2+-induced Ca2+ release. This is consistent with the hypothesis that Polycystin-2 in Dictyostelium is not itself Ca2+-regulated, as predicted by its lack of sequence motifs for known Ca2+- or Ca2+-calmodulin-binding sites [29].

3.3.2. Resting Ca2+ Levels Are Altered by Changing pkd2 Expression

The ability of cells to maintain appropriate [Ca2+]c is crucial for tight regulation of the many Ca2+-regulated cellular processes. Assessment of the basal [Ca2+]c in the pkd2 mutant strains revealed no significant correlation between copy number and resting Ca2+ levels, therefore data from all transformants within each group were pooled to calculate the mean (Figure 6A,B). The results showed significant reductions in the basal [Ca2+]c of KD strains compared to the control, both in the vegetative (p < 0.01) and developed states (p < 0.05). However, there was no significant difference in the basal [Ca2+]c of pkd2-overexpressing strains compared to control. These results show that Polycystin-2 not only contributes to cytosolic Ca2+ transients in chemoattractant responses but also contributes to basal Ca2+ homeostasis in unstimulated cells. The magnitude of this contribution is smaller when Polycystin-2 levels are reduced but is already at or close to its maximum at wild-type expression levels and unresponsive to overexpression.

3.4. pkd2 Expression Levels Affect Fruiting Body Morphologies and Spore Viability

In Dictyostelium, starvation triggers multicellular development, leading to the formation of mature fruiting bodies consisting of spore heads, stalks and basal discs (Figure 7A shows a wild-type AX2 fruiting body). Cells that differentiate into stalk and disk cells undergo a form of autophagic cell death [52,53], and the viable spores in the sorus can disperse and grow into amoebae when conditions improve. Aberrant Ca2+ signalling affects downstream processes, including multicellular morphogenesis [54] (Schaap et al. (1996)). Prolonged elevation of cytosolic Ca2+ levels (as occurs during multicellular development) mediates the induction of prestalk gene ecmB and stalk cell differentiation by the Dictyostelium morphogen DIF (Differentiation Inducing Factor) [55]. In the present study, when pkd2 expression was knocked down, transformants developed into fruiting bodies with very thin fragile stalks that were often unable to support the sorus (Figure 7B). Conversely, when we overexpressed pkd2, cytosolic Ca2+ signalling was enhanced and the transformants developed fruiting bodies with very thick stalks, presumably as a consequence of excess stalk cell differentiation (Figure 7C).
Dictyostelium spores remain dormant until activated for germination, a process involving Ca2+ signalling [43,56]. Upon spore activation, Ca2+ is released through IP3-dependent Ca2+ release and subsequent CaM-dependent efflux. During amoebal emergence, Ca2+ uptake is essential for emergence-specific protein production [57]. We evaluated spore viability in Polycystin-2 mutant strains by harvesting and heat-activating spores, and then plating them on Enterobacter lawns. Results showed significantly decreased spore viability in overexpression strains compared to KD strains (Figure 8). While we expected that the increased calcium signalling in the Polycystin-2 overexpression strains may have increased spore viability, one possibility is that elevated Ca2+ levels/responses caused by Polycystin-2 overexpression caused increased premature spore germination in the sorus of the fruiting body, so a higher proportion is not viable on the plated lawns.

3.5. Polycystin-2 Positively Regulates Growth Rates and Nutrient Uptake via Phagocytosis and Pinocytosis

Calcium signalling plays a vital role in endocytic processes including pinocytosis and phagocytosis. It controls vesicle formation, membrane trafficking and cytoskeletal dynamics involved in endocytosis [58]. It also regulates proteins and enzymes responsible for vesicle formation and fusion [59,60]. Similarly, calcium signalling regulates various steps of phagocytosis, including particle recognition, engulfment and vesicle formation. It Influences cytoskeletal rearrangements, receptor activation and signalling molecule recruitment during phagocytosis [61]. Therefore, it was crucial to assess these processes in our Polycystin-2 mutant strains to identify any abnormal phenotypes. We evaluated pinocytosis by measuring the uptake of FITC-dextran over a 70 min period. To determine the rates of phagocytosis, we measured the uptake of fluorescently labelled live E. coli cells over a 30 min duration. The uptake of DsRed-labelled E. coli and FITC-dextran HL5 both showed a positive correlation with the Polycystin-2 expression index and are therefore positively regulated by Polycystin-2, as illustrated in Figure 9A,B.
We proceeded to investigate whether the observed heightened nutrient uptake in our mutants translated into improved growth rates. Other studies on Polycystin-2 KO cells have yielded conflicting results regarding growth rates [31,33]. Our investigation revealed that the increased rates of pinocytosis and phagocytosis resulting from increased pkd2 expression corresponded with faster axenic growth and plaque expansion rates on bacterial lawns (Figure 10A,B). These findings provide compelling evidence that the altered rates of axenic growth and plaque expansion in Polycystin-2 transformants are a result of altered rates of pinocytosis and phagocytosis.

3.6. Polycystin-2 Expression Affects the Endolysosomal Vesicles

Our results indicate that Polycystin-2 expression can influence endocytic processes and autophagic cell death. Given that Polycystin-2 expression has been detected in recycling and early endocytic compartments and is involved in controlling lysosomal exocytosis [30], we decided to further assess how Polycystin-2 expression levels affect the vesicles of the endolysosomal compartments. We stained vegetative cells with LysoSensorTM Blue DND-167, a fluorescent dye with a pKa of ~5.1, that accumulates in acidic organelles within cells, particularly lysosomes, and becomes more fluorescent in acidic environments. The recorded fluorescence increased as Polycystin-2 expression increased, indicating that Polycystin-2 either increases lysosomal mass or, because LysoSensor™ Blue DND-167 fluorescence increases in acidic environments, increases the acidification (decreased pH) in these compartments (Figure 11).

4. Discussion

In this study, Polycystin-2 function in Dictyostelium was investigated by knocking down and overexpressing pkd2 mRNA and assaying a variety of phenotypic readouts in transformants with different levels of expression. In the absence of a specific anti-Polycystin-2 antibody, we were unable to measure the levels of the protein itself. However, the fact that the phenotypic outcomes were correlated with mRNA expression levels supports the inference that the protein levels were also correlated with the copy numbers of the antisense and overexpression constructs. Polycystin-2′s role in chemotactic Ca2+ signalling was assessed using in vivo expression of the Ca2+-sensitive luminescent protein, and aequorin and chemotactic Ca2+ responses in these transformants were characterized. As Dictyostelium is an excellent model organism for the analysis of the pathophysiology behind many diseases, its potential use as a model for ADPKD was assessed.
Polycystin-2 in the Dictyostelium parental strains DH1-10 and AX2 cells localizes at the plasma membrane [30,31,34], which suggests that it may indeed be a Ca2+ channel facilitating extracellular Ca2+ influx. To investigate whether Polycystin-2 can contribute to calcium influx, we measured cytosolic Ca2+ responses to chemoattractants in Polycystin-2 knockdown (KD) and overexpression transformants. If Polycystin-2 was capable of contributing to the Ca2+ responses, we expected that overexpressing and knocking down the expression of the protein would increase and decrease the Ca2+ responses, respectively. Indeed, analysis of cytosolic Ca2+ responses revealed that they were significantly altered. Overexpressing Polycystin-2 significantly amplified the magnitude of the Ca2+ responses to 1µM cAMP and 1µM folic acid compared to wild type. Furthermore, in KD transformants, the Ca2+ responses were reduced, as were the basal cytosolic Ca2+ levels. These results imply not only that Polycystin-2 contributes to the responses but also to maintaining the cell’s resting Ca2+ levels.
Analysis of the maximum rise and fall rates of cytosolic Ca2+ in Polycystin-2 mutants revealed the same relationship in response kinetics to both cAMP and folic acid and shows that the Ca2+-regulated Ca2+ channels and pumps are the same for the two attractants since responses to them exhibit the same kinetic properties. The relationship between the response onset time and response magnitude was negative for Polycystin-2 overexpression, KD and control strains, and in this respect, is similar to the relationship previously reported for wild-type, calnexin-deficient and calreticulin-deficient strains [29]. However, in this work, each set of strains falls on a different line so that, in overexpression strains, the response magnitude is greater than the controls by a constant amount at all response times. Conversely, in the KD strains, the response magnitude is reduced by a constant amount, independent of response times, compared to controls. The simplest explanation is that Polycystin-2 is itself a significant contributor to the Ca2+ responses at all response times and magnitudes, but that the mechanism by which the response time and magnitude are coupled is unchanged, e,g., in the form of Ca2+-induced Ca2+ release. This makes sense if Polycystin-2′s contribution to Ca2+ responses is not Ca2+-regulated, as expected since the Polycystin-2 sequence does not contain recognizable Ca2+- or Ca2+-calmodulin-binding sites [29]. These results provide compelling evidence for Polycystin-2 as a Ca2+ channel. However, Polycystin-2 cannot be the only plasma membrane calcium channel involved in chemotactic calcium responses because Polycystin-2 KO cells still retain their calcium responses when stimulated with cAMP and folic acid [31]. Additionally, Polycystin-2 KO cells are still able to undergo chemotaxis towards a source of folic acid [30]. This does not exclude the possibility of Polycystin-2 contributing to these Ca2+ responses given the overlapping and redundant functions of many calcium channels and pumps. Our results therefore show that Polycystin-2 does contribute to calcium influx during calcium responses to cAMP and folic acid even though it is not essential for them.
If Polycystin-2 is not directly gated by either of the chemoattractants used in this work (folate and cAMP), both of which interact with known G-protein-coupled receptors, and is not responsive to intracellular Ca2+ levels either, what might be the signal that controls its activity during responses to these chemoattractants? The answer might lie in Polycystin-2′s ability to interact with other plasma membrane proteins, as is the case with its mammalian counterpart. A candidate calcium channel that may reside at the plasma membrane to facilitate calcium influx is IplA, a putative calcium channel in Dictyostelium resembling InsP3 receptors [62]. Indeed, a double KO of Polycystin-2/IplA completely lacks chemotactic calcium responses [31]. This prompts the question of whether there exists an interaction between the two proteins, and when they are co-localized within the same sub-cellular compartment, whether they jointly contribute to the cytosolic Ca2+ response. Indeed, in other organisms, InsP3 receptors and Polycystin-2 can directly interact to form a functional complex. InsP3 receptors have been found to gate PC2 channel activity by interactions between the two channels through acidic residues in the N-terminal ligand-binding domain of the InsP3 receptor and the C-terminal ER retention signal of PC2 [13,15]. In Dictyostelium, coimmunoprecipitations of IplA and Polycystin-2 would uncover whether the channels also interact. Intriguingly, Polycystin-2 was shown by Traynor and Kay (2017) [31] to be essential for Ca2+ responses to extracellular ATP, suggesting that it may interact with purinergic receptors [63]. Another potential interaction partner of Polycystin-2 is the putative PC1 homologue that is encoded in the Dictyostelium genome (dictyBase gene ID: DDB_G0289409). Characterization of this protein is needed to determine its involvement in Ca2+ signalling and to reveal whether it functions as a PC1-like protein interacting with Polycystin-2.
Aberrant Ca2+ signalling can have a profound impact on numerous Ca2+-dependent cellular processes. However, previous reports regarding the phenotypic effects of Polycystin-2 knockout have yielded conflicting results among different laboratories. While some knockout strains exhibited rheotaxis defects [30], others did not [31,35]. Similarly, growth defects were observed in some KO strains [33], but not in others [31]. These varying phenotypes may be subtle and not easily detectable in a binary comparison of KO versus wild-type cells.
In order to uncover more nuanced phenotypes, our experiments employed KD and overexpression, an approach that allows the correlation of phenotypic severity with an expression index in multiple, independently isolated strains. The results revealed that Polycystin-2 positively regulates growth rates, as well as the nutrient uptake processes of macropinocytosis and phagocytosis. The defects observed in the overexpression strains were more pronounced, but the defects in the KD strains were mild, perhaps explaining some of the undetected phenotypes in Polycystin-2 KO strains from other studies. In our study, a strong correlation between the Polycystin-2 expression index and the phenotypic defects highlighted the regulatory role of Polycystin-2 in these processes. Polycystin-2 likely modulates Ca2+ signalling, as many steps of the endocytic pathway in mammalian cells are known to be Ca2+-regulated and the vesicle sources of stored calcium [64,65].
In favour of a regulatory role of Polycystin-2-dependent Ca2+ signalling in endosomal trafficking, KO cells had reduced Ca2+-stimulated lysosome exocytosis [30]. Other studies suggest that Ca2+ signalling is involved in the endocytic process in Dictyostelium. For example, KO mutants of fAR1 (the folate receptor in proliferating cells), upon binding to bacteria, have a greatly reduced ability to induce actin polymerization or produce phagocytic cups, potentially due to the absence of fAR1-associated chemotactic signalling which involves Ca2+ [51,66]. The calcium-regulated actin-bundling protein, fibrin, is associated with both the macrophagosome and macropinosome during formation [67]. Furthermore, the Ca2+-binding proteins calnexin and calreticulin are essential for the formation of the phagocytic cup [68]. Given its location at the plasma, recycling endosome and newly formed endosome membranes [30], Polycystin-2 is well-situated to contribute to the regulation of membrane fusion/fission by Ca2+ signalling in these early events.
An indication that Polycystin-2 regulates other processes along the endolysosomal pathway is evident, as cells stained with Lysosensor Blue™ displayed either decreased or increased fluorescence in our Polycystin-2 KD or overexpression strains, respectively. These changes in fluorescence could represent decreased or increased lysosomal mass, respectively, or changes in the pH of the lysosomal compartments. The luminal calcium concentration of endocytic vesicles has been linked to acidification [69], so the presence of Polycystin-2 in the membrane of early endosomes may help to control calcium homeostasis during acidification. We saw similar abnormalities in lysosomal mass or acidification in Dictyostelium strains when knocking down or overexpressing the calcium channel, mucolipin, another TRP channel that localizes to endocytic compartments [41]. Changes in lysosomal mass could signify abnormalities in progression through the interconnected endocytic and autophagic pathways [70], both of which are, in part, regulated by calcium signalling [71,72]. For instance, if lysosomes fail to fuse properly with autophagosomes during the autophagy process, the undegraded contents of autophagosomes can accumulate in the cell, along with an increased number of lysosomes.
Indeed, we did observe indications of abnormalities in autophagic cell death in our Polycystin-2 strains. The autophagic cell death pathway in Dictyostelium plays an important role in multicellular development leading to the differentiation of stalk cells, a process that is mediated by DIF, which induces prolonged, elevated intracellular Ca2+ levels and induces expression of the prestalk cell gene ecmB [55]. Our Polycystin-2 KD and overexpression strains exhibited abnormal stalk cell differentiation—the overexpression strains developed short thick stalks while the knockdown strains had thin, fragile stalks reminiscent of the delicate fruiting bodies frequently observed to collapse in Polycystin-2 KO cells [31]. This implicates Polycystin-2 mediated calcium signalling in stalk cell differentiation; however, as Polycystin-2 KO cells still retain their calcium responses to DIF stimulation [31], other calcium channels must also be involved. The differentiation of stalk and disk cells represents a form of autophagic cell death in Dictyostelium [52,53], and shorter thicker stalks have been associated with more cells entering the stalk differentiation and autophagic cell death pathway [38]. These phenotypes may reflect aberrant Ca2+ signalling and suggest that precise control of Ca2+ release by Polycystin-2 is necessary to maintain normal stalk/spore proportions within the population. This process is known to be Ca2+-regulated as cell-type specific differentiation into prespore and prestalk cells is controlled partly by Ca2+, such that higher Ca2+ levels tend to direct cells to the prestalk pathway and lower Ca2+ direct cells to the prespore pathway [54,55,73,74,75,76].
Defective autophagy is reported in ADPKD [77], and a role for PC2-dependent Ca2+ signalling in autophagy is emerging [78,79,80]. The overexpression of PC2 has been shown to induce autophagy, which was attenuated by the Ca2+ chelator BAPTA-AM, suggesting the regulation of autophagy by PC2 is contingent on intracellular calcium control [78]. In human cardiomyocytes derived from embryonic stem cells, PC2 knockdown reduces caffeine-induced cytosolic Ca2+ rise and autophagic flux during glucose starvation, affecting the activation of the key central signalling complexes AMP-activated protein kinase (AMPK) and mammalian target of rapamycin (mTOR) [81]. PC2 activity is also essential for inducing autophagy under hyperosmotic stress in HeLa and HCT116 cells via the mTOR pathway [80]. These parallels with our findings confirm that Dictyostelium is an ideal model for studying autophagy and autophagic cell death [82,83], and given the extensive knowledge available AMPK and DdTOR signalling in Dictyostelium [38,84,85,86,87], this model system offers invaluable opportunities to investigate Polycystin-2-regulated autophagy and the underlying signalling pathways.

5. Conclusions

This study has provided evidence that Polycystin-2 contributes to cytosolic Ca2+ signalling in response to chemotactic stimuli in Dictyostelium. Further, Polycystin-2 dependent Ca2+-signalling must be tightly controlled to regulate downstream Ca2+-sensitive processes such as endocytosis, growth and autophagic cell death. Importantly, this study has also highlighted the potential to use Dictyostelium as a model to study the underlying molecular functioning behind ADPKD.

Author Contributions

Conceptualization, P.R.F. and C.Y.A.; methodology, P.R.F., C.Y.A., and O.S.; formal analysis, C.Y.A. and P.R.F.; investigation, C.Y.A. and O.S.; data curation, C.Y.A.; writing—original draft preparation, C.Y.A.; writing—review and editing, P.R.F. and O.S.; supervision, P.R.F.; funding acquisition, P.R.F. All authors have read and agreed to the published version of the manuscript.

Funding

This work was partly funded by the Australian Research Council Discovery Project Grant number DP140104276. CYA was supported by an Australian Postgraduate Research Award for part of this work.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study are available upon request from the corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Wu, G.; D’Agati, V.; Cai, Y.; Markowitz, G.; Park, J.H.; Reynolds, D.M.; Maeda, Y.; Le, T.C.; Hou, H.; Kucherlapati, R.; et al. Somatic Inactivation of Polycystin 2 Results in Polycystic Kidney Disease. Cell 1998, 93, 177–188. [Google Scholar] [CrossRef] [PubMed]
  2. Roitbak, T.; Ward, C.J.; Harris, P.C.; Bacallao, R.; Ness, S.A.; Wandinger-Ness, A. A Polycystin-1 Multiprotein Complex Is Disrupted in Polycystic Kidney Disease Cells. Mol. Biol. Cell 2004, 15, 1334–1346. [Google Scholar] [CrossRef] [PubMed]
  3. Fallah, H.P.; Ahuja, E.; Lin, H.; Qi, J.; He, Q.; Gao, S.; An, H.; Zhang, J.; Xie, Y.; Liang, D. A Review on the Role of TRP Channels and Their Potential as Drug Targets: An Insight Into the TRP Channel Drug Discovery Methodologies. Front. Pharmacol. 2022, 13, 914499. [Google Scholar] [CrossRef] [PubMed]
  4. Luo, Y.; Vassilev, P.M.; Li, X.; Kawanabe, Y.; Zhou, J. Native Polycystin-2 Functions as a Plasma Membrane Ca2+-Permeable Cation Channel in Renal Epithelia. Mol. Cell Biol. 2003, 23, 2600–2607. [Google Scholar] [CrossRef] [PubMed]
  5. Ma, R.; Li, W.P.; Rundle, D.; Kong, J.; Akbarali, H.I.; Tsiokas, L. PKD2 Functions as an Epidermal Growth Factor-Activated Plasma Membrane Channel. Mol. Cell Biol. 2005, 25, 8285–8298. [Google Scholar] [CrossRef] [PubMed]
  6. Nauli, S.M.; Alenghat, F.J.; Luo, Y.; Williams, E.; Vassilev, P.; Li, X.; Elia, A.E.H.; Lu, W.; Brown, E.M.; Quinn, S.J.; et al. Polycystins 1 and 2 Mediate Mechanosensation in the Primary Cilium of Kidney Cells. Nat. Genet. 2003, 33, 129–137. [Google Scholar] [CrossRef]
  7. Pazour, G.J.; San Agustin, J.T.; Follit, J.A.; Rosenbaum, J.L.; Witman, G.B. Polycystin-2 Localizes to Kidney Cilia, and the Ciliary Level Is Elevated in Orpk Mice with Polycystic Kidney Disease. Curr. Biol. 2002, 12, R378–R380. [Google Scholar] [CrossRef] [PubMed]
  8. Cai, Y.; Maeda, Y.; Cedzich, A.; Torres, V.E.; Wu, G.; Hayashi, T.; Mochizuki, T.; Park, J.H.; Witzgall, R.; Somlo, S. Identification and Characterization of Polycystin-2, the PKD2 Gene Product. J. Biol. Chem. 1999, 274, 28557–28565. [Google Scholar] [CrossRef] [PubMed]
  9. Koulen, P.; Cai, Y.; Geng, L.; Maeda, Y.; Nishimura, S.; Witzgall, R.; Ehrlich, B.E.; Somlo, S. Polycystin-2 Is an Intracellular Calcium Release Channel. Nat. Cell Biol. 2002, 4, 191–197. [Google Scholar] [CrossRef]
  10. Hanaoka, K.; Qian, F.; Boletta, A.; Bhunia, A.K.; Piontek, K.; Tsiokas, L.; Sukhatme, V.P.; Guggino, W.B.; Germino, G.G. Co-assembly of Polycystin-1 and -2 Produces Unique Cation-Permeable Currents. Nature 2000, 408, 990–994. [Google Scholar] [CrossRef]
  11. Padhy, B.; Xie, J.; Wang, R.; Lin, F.; Huang, C.L. Channel Function of Polycystin-2 in the Endoplasmic Reticulum Protects Against Autosomal Dominant Polycystic Kidney Disease. J. Am. Soc. Nephrol. 2022, 33, 1501–1516. [Google Scholar] [CrossRef]
  12. Liu, X.; Tang, J.; Chen, X.Z. Role of PKD2 in the Endoplasmic Reticulum Calcium Homeostasis. Front. Physiol. 2022, 13, 962571. [Google Scholar] [CrossRef] [PubMed]
  13. Li, Y.; Wright, J.M.; Qian, F.; Germino, G.G.; Guggino, W.B. Polycystin 2 Interacts with Type I Inositol 1,4,5-Trisphosphate Receptor to Modulate Intracellular Ca2+ Signaling. J. Biol. Chem. 2005, 280, 41298–41306. [Google Scholar] [CrossRef] [PubMed]
  14. Anyatonwu, G.I.; Estrada, M.; Tian, X.; Somlo, S.; Ehrlich, B.E. Regulation of Ryanodine Receptor-Dependent Calcium Signalling by Polycystin-2. Proc. Natl. Acad. Sci. USA 2007, 104, 6454–6459. [Google Scholar] [CrossRef] [PubMed]
  15. Sammels, E.; Devogelaere, B.; Mekahli, D.; Bultynck, G.; Missiaen, L.; Parys, J.B.; Cai, Y.; Somlo, S.; De Smedt, H. Polycystin-2 Activation by Inositol 1,4,5-Trisphosphate-Induced Ca2+ Release Requires Its Direct Association with the Inositol 1,4,5-Trisphosphate Receptor in a Signaling Microdomain. J. Biol. Chem. 2010, 285, 18794–18805. [Google Scholar] [CrossRef] [PubMed]
  16. Yamaguchi, T.; Wallace, D.P.; Magenheimer, B.S.; Hempson, S.J.; Grantham, J.J.; Calvet, J.P. Calcium restriction allows cAMP activation of the B-Raf/ERK pathway, switching cells to a cAMP-dependent growth-stimulated phenotype. J. Biol. Chem. 2004, 279, 40419–40430. [Google Scholar] [CrossRef] [PubMed]
  17. Ye, M.; Grantham, J.J. The Secretion of Fluid by Renal Cysts from Patients with Autosomal Dominant Polycystic Kidney Disease. N. Engl. J. Med. 1993, 329, 310–313. [Google Scholar] [CrossRef] [PubMed]
  18. Li, L.X.; Fan, L.X.; Zhou, J.X.; Grantham, J.J.; Calvet, J.P.; Sage, J.; Li, X. Lysine Methyltransferase SMYD2 Promotes Cyst Growth in Autosomal Dominant Polycystic Kidney Disease. J. Clin. Investig. 2017, 127, 2751–2764. [Google Scholar] [CrossRef] [PubMed]
  19. Brill, A.L.; Ehrlich, B.E. Polycystin 2: A calcium channel, channel partner, and regulator of calcium homeostasis in ADPKD. Cell Signal. 2020, 66, 109490. [Google Scholar] [CrossRef]
  20. Kahveci, A.S.; Barnatan, T.T.; Kahveci, A.; Adrian, A.E.; Arroyo, J.; Eirin, A.; Harris, P.C.; Lerman, A.; Lerman, L.O.; Torres, V.E.; et al. Oxidative Stress and Mitochondrial Abnormalities Contribute to Decreased Endothelial Nitric Oxide Synthase Expression and Renal Disease Progression in Early Experimental Polycystic Kidney Disease. Int. J. Mol. Sci. 2020, 21, 1994. [Google Scholar] [CrossRef]
  21. Lu, Y.; Sun, Y.; Liu, Z.; Lu, Y.; Zhu, X.; Lan, B.; Mi, Z.; Dang, L.; Li, N.; Zhan, W.; et al. Activation of NRF2 Ameliorates Oxidative Stress and Cystogenesis in Autosomal Dominant Polycystic Kidney Disease. Sci. Transl. Med. 2020, 12, eaba3613. [Google Scholar] [CrossRef] [PubMed]
  22. Fan, L.X.; Zhou, X.; Sweeney, W.E., Jr.; Wallace, D.P.; Avner, E.D.; Grantham, J.J.; Li, X. Smac-Mimetic–Induced Epithelial Cell Death Reduces the Growth of Renal Cysts. J. Am. Soc. Nephrol. 2013, 24, 2010–2022. [Google Scholar] [CrossRef] [PubMed]
  23. Nowak, K.L.; Edelstein, C.L. Apoptosis and Autophagy in Polycystic Kidney Disease (PKD). Cell Signal. 2020, 68, 109518. [Google Scholar] [CrossRef] [PubMed]
  24. Sieben, C.J.; Harris, P.C. Experimental Models of Polycystic Kidney Disease: Applications and Therapeutic Testing. Kidney360 2023, 4, 1155–1173. [Google Scholar] [CrossRef] [PubMed]
  25. Ward, C.J.; Sharma, M. Polycystic Kidney Disease: Lessons Learned from Caenorhabditis elegans Mating Behavior. Curr. Biol. 2015, 25, R1168–R1170. [Google Scholar] [CrossRef] [PubMed]
  26. Watnick, T.J.; Jin, Y.; Matunis, E.; Kernan, M.J.; Montell, C. A Flagellar Polycystin-2 Homolog Required for Male Fertility in Drosophila. Curr. Biol. 2003, 13, 2179–2184. [Google Scholar] [CrossRef]
  27. Van Goethem, E.; Silva, E.A.; Xiao, H.; Franc, N.C. The Drosophila TRPP Cation Channel, PKD2 and Dmel/Ced-12 Act in Genetically Distinct Pathways During Apoptotic Cell Clearance. PLoS ONE 2012, 7, e31488. [Google Scholar] [CrossRef]
  28. Menezes, L.F.; Germino, G.G. Murine Models of Polycystic Kidney Disease. Drug Discov. Today Dis. Mech. 2013, 10, e153–e158. [Google Scholar] [CrossRef]
  29. Wilczynska, Z.; Schlatterer, C.; Muller-Taubenberger, A.; Malchow, D.; Fisher, P.R. Release of Ca2+ from the Endoplasmic Reticulum Contributes to Ca2+ Signalling in Dictyostelium. Eukaryot. Cell 2005, 4, 1513–1525. [Google Scholar] [CrossRef]
  30. Lima, W.C.; Vinet, A.; Pieters, J.; Cosson, P. Role of PKD2 in Rheotaxis in Dictyostelium. PLoS ONE 2014, 9, e88682. [Google Scholar] [CrossRef]
  31. Traynor, D.; Kay, R.R. A Polycystin-Type Transient Receptor Potential (Trp) Channel That Is Activated by ATP. Biology Open 2017, 6, 200–209. [Google Scholar] [CrossRef] [PubMed]
  32. Fey, P.; Dodson, R.J.; Basu, S.; Chisholm, R.L. One stop shop for everything Dictyostelium: DictyBase and the Dicty Stock Center in 2012. Methods Mol. Biol. 2013, 983, 59–92. [Google Scholar] [CrossRef] [PubMed]
  33. Waheed, A.; Ludtmann, M.H.R.; Pakes, N.; Robery, S.; Kuspa, A.; Dinh, C.; Baines, D.; Williams, R.S.B.; A Carew, M. Naringenin Inhibits the Growth of Dictyostelium and MDCK-Derived Cysts in a Polycystin-2 (TRPP2)-Dependent Manner. Br. J. Pharmacol. 2014, 171, 2659–2670. [Google Scholar] [CrossRef] [PubMed]
  34. Allan, C.Y. Calcium Signalling in Dictyostelium. Ph.D. Thesis, La Trobe University Australia, Bundoora, Australia, 2022. [Google Scholar]
  35. Artemenko, Y.; Axiotakis, L., Jr.; Borleis, J.; Iglesias, P.A.; Devreotes, P.N. Chemical and Mechanical Stimuli Act on Common Signal Transduction and Cytoskeletal Networks. Proc. Natl. Acad. Sci. USA 2016, 113, E7500–E7509. [Google Scholar] [CrossRef] [PubMed]
  36. Wilczynska, Z.; Barth, C.; Fisher, P.R. Mitochondrial mutations impair signal transduction in Dictyostelium discoideum slugs. Biochem. Biophys. Res. Commun. 1997, 234, 39–43. [Google Scholar] [CrossRef] [PubMed]
  37. Kotsifas, M.; Barth, C.; Lay, S.T.; Lozanne, A.; Fisher, P.R. Chaperonin 60 and mitochondrial disease in Dictyostelium. J. Muscle Res. Cell Motil. 2002, 23, 839–852. [Google Scholar] [CrossRef] [PubMed]
  38. Bokko, P.B.; Francione, L.; Bandala-Sanchez, E.; Ahmed, A.U.; Annesley, S.J.; Huang, X.; Khurana, T.; Kimmel, A.R.; Fisher, P.R. Diverse cytopathologies in mitochondrial disease are caused by AMP-activated protein kinase signalling. Mol. Biol. Cell 2007, 18, 1874–1886. [Google Scholar] [CrossRef] [PubMed]
  39. Nellen, W.; Silan, C.; Firtel, R.A. DNA-Mediated transformation in Dictyostelium discoideum: Regulated expression of an actin gene fusion. Mol. Cell Biol. 1984, 4, 2890–2898. [Google Scholar] [CrossRef]
  40. Wilczynska, Z.; Fisher, P.R. Analysis of a complex plasmid insertion in a phototaxis-deficient transformant of Dictyostelium discoideum selected on a Micrococcus luteus lawn. Plasmid 1994, 32, 182–194. [Google Scholar] [CrossRef]
  41. Allan, C.Y.; Fisher, P.R. The Dictyostelium Model for Mucolipidosis Type IV. Front. Cell Dev. Biol. 2022, 10, 741967. [Google Scholar] [CrossRef]
  42. Maselli, A.; Laevsky, G.; Knecht, D.A. Kinetics of binding, uptake and degradation of live fluorescent (DsRed) bacteria by Dictyostelium discoideum. Microbiology 2002, 148, 413–420. [Google Scholar] [CrossRef] [PubMed]
  43. Cotter, D.A.; Raper, K.B. Spore germination in Dictyostelium discoideum. Proc. Natl. Acad. Sci. USA 1966, 56, 880–887. [Google Scholar] [CrossRef] [PubMed]
  44. Cotter, D.A.; Raper, K.B. Properties of germinating spores of Dictyostelium discoideum. J. Bacteriol. 1968, 96, 1680–1689. [Google Scholar] [CrossRef] [PubMed]
  45. Kessin, R.H. Dictyostelium—Evolution, Cell Biology, and the Development of Multicellularity; Cambridge University Press: New York, NY, USA, 2001. [Google Scholar]
  46. Van Driessche, N.; Shaw, C.; Katoh, M.; Morio, T.; Sucgang, R.; Ibarra, M.; Kuwayama, H.; Saito, T.; Urushihara, H.; Maeda, M.; et al. A transcriptional profile of multicellular development in Dictyostelium discoideum. Development 2002, 129, 1543–1552. [Google Scholar] [CrossRef] [PubMed]
  47. Parikh, A.; Miranda, E.R.; Katoh-Kurasawa, M.; Fuller, D.; Rot, G.; Zagar, L.; Curk, T.; Sucgang, R.; Chen, R.; Zupan, B.; et al. Conserved developmental transcriptomes in evolutionarily divergent species. Genome. Biol. 2010, 11, R35. [Google Scholar] [CrossRef] [PubMed]
  48. Stajdohar, M.; Jeran, L.; Kokosar, J.; Blenkus, D.; Janez, T.; Kuspa, A.; Shaulsky, G.; Zupan, B. dictyExpress: Visual Analytics of NGS Gene Expression in Dictyostelium. 2015. Available online: https://www.dictyexpress.org (accessed on 20 March 2024).
  49. Stajdohar, M.; Rosengarten, R.D.; Kokosar, J.; Jeran, L.; Blenkus, D.; Shaulsky, G.; Zupan, B. dictyExpress: A web-based platform for sequence data management and analytics in Dictyostelium and beyond. BMC Bioinform. 2017, 18, 291. [Google Scholar] [CrossRef] [PubMed]
  50. Barth, C.; Fraser, D.J.; Fisher, P.R. Co-insertional replication is responsible for tandem multimer formation during plasmid integration into the Dictyostelium genome. Sci. Direct. 1998, 39, 141–153. [Google Scholar] [CrossRef]
  51. Nebl, T.; Fisher, P.R. Intracellular Ca2+ responses by Dictyostelium amoebae to nanomolar chemoattractant stimuli are mediated exclusively by Ca2+ influx. J. Cell Sci. 1997, 110, 2845–2853. [Google Scholar] [CrossRef]
  52. Giusti, C.; Tresse, E.; Luciani, M.F.; Golstein, P. Autophagic cell death: Analysis in Dictyostelium. Biochim. Biophys. Acta. 2009, 1793, 1422–1431. [Google Scholar] [CrossRef]
  53. Giusti, C.; Luciani, M.F.; Ravens, S.; Gillet, A.; Golstein, P. Autophagic cell death in Dictyostelium requires the receptor histidine kinase DhkM. Mol. Biol. Cell 2010, 21, 1825–1835. [Google Scholar] [CrossRef]
  54. Poloz, Y.; O’Day, D.H. Ca2+ signaling regulates ecmB expression, cell differentiation and slug regeneration in Dictyostelium. Differentiation 2012, 84, 163–175. [Google Scholar] [CrossRef] [PubMed]
  55. Schaap, P.; Nebl, T.; Fisher, P.R. A slow sustained increase in cytosolic Ca2+ levels mediates stalk gene induction by differentiation-inducing factor in Dictyostelium. EMBO J. 1996, 15, 5177–5183. [Google Scholar] [CrossRef] [PubMed]
  56. Cotter, D.A.; Sands, T.W.; Virdy, K.J.; North, M.J.; Klein, G.; Satre, M. Patterning of development in Dictyostelium discoideum factors regulating growth, differentiation, spore dormancy and germination. Biochem. Cell Biol. 1992, 70, 892–919. [Google Scholar] [CrossRef] [PubMed]
  57. Lydan, M.A.; Cotter, D.A. The role of Ca2+ during spore germination in Dictyostelium: Autoactivation is mediated by the mobilization of Ca2+ while amoebal emergence requires entry of external Ca2+. J. Cell Sci. 1995, 108, 1921–1930. [Google Scholar] [CrossRef] [PubMed]
  58. Gundu, C.; Arruri, V.K.; Yadav, P.; Navik, U.; Kumar, A.; Amalkar, V.S.; Vikram, A.; Gaddam, R.R. Dynamin-Independent Mechanisms of Endocytosis and Receptor Trafficking. Cells 2022, 11, 2557. [Google Scholar] [CrossRef] [PubMed]
  59. Pryor, P.R.; Mullock, B.M.; Bright, N.A.; Gray, S.R.; Luzio, J.P. The role of intraorganellar Ca2+ in late endosome-lysosome heterotypic fusion and in the reformation of lysosomes from hybrid organelles. J. Cell Biol. 2000, 149, 1053–1062. [Google Scholar] [CrossRef] [PubMed]
  60. Brunger, A.T.; Leitz, J.; Zhou, Q.; Choi, U.B.; Lai, Y. Ca2+-Triggered Synaptic Vesicle Fusion Initiated by Release of Inhibition. Trends. Cell Biol. 2018, 28, 631–645. [Google Scholar] [CrossRef] [PubMed]
  61. Nunes, P.; Demaurex, N. The role of calcium signaling in phagocytosis. J. Leukocyte Biol. 2010, 88, 57–68. [Google Scholar] [CrossRef]
  62. Traynor, D.; Milne, J.L.; Insall, R.H.; Kay, R.R. Ca2+ signalling is not required for chemotaxis in Dictyostelium. EMBO J. 2000, 19, 4846–4854. [Google Scholar] [CrossRef]
  63. Ludlow, M.J.; Traynor, D.; Fisher, P.R.; Ennion, S.J. Purinergic-mediated Ca2+ influx in Dictyostelium discoideum. Cell Calcium 2008, 44, 567–579. [Google Scholar] [CrossRef]
  64. Luzio, J.P.; Bright, N.A.; Pryor, P.R. The role of calcium and other ions in sorting and delivery in the late endocytic pathway. Biochem. Soc. Trans. 2007, 35, 1088–1091. [Google Scholar] [CrossRef] [PubMed]
  65. Patel, S.; Cai, X. Evolution of acidic Ca2+ stores and their resident Ca2+-permeable channels. Cell Calcium 2015, 57, 222–230. [Google Scholar] [CrossRef] [PubMed]
  66. Pan, M.; Xu, X.; Chen, Y.; Jin, T. Identification of a chemoattractant G Protein-Coupled Receptor for folic acid that controls both chemotaxis and phagocytosis. Dev. Cell 2016, 36, 428–439. [Google Scholar] [CrossRef] [PubMed]
  67. Pikzack, C.; Prassler, J.; Furukawa, R.; Fechheimer, M.; Rivero, F. Role of calcium-dependent actin-bundling proteins: Characterization of Dictyostelium mutants lacking fimbrin and the 34-kilodalton protein. Cell Motil. Cytoskel. 2005, 62, 210–231. [Google Scholar] [CrossRef] [PubMed]
  68. Muller-Taubenberger, A.; Lupas, A.N.; Li, H.; Ecke, M.; Simmeth, E.; Gerisch, G. Calreticulin and calnexin in the endoplasmic reticulum are important for phagocytosis. EMBO J. 2001, 20, 6772–6782. [Google Scholar] [CrossRef] [PubMed]
  69. Gerasimenko, J.V.; Tepikin, A.V.; Petersen, O.H.; Gerasimenko, O.V. Calcium uptake via endocytosis with rapid release from acidifying endosomes. Curr. Biol. 1998, 8, 1335–1338. [Google Scholar] [CrossRef] [PubMed]
  70. Birgisdottir, Å.B.; Johansen, T. Autophagy and endocytosis—Interconnections and interdependencies. J. Cell Sci. 2020, 133, jcs228114. [Google Scholar] [CrossRef]
  71. Medina, D.L.; Di Paola, S.; Peluso, I.; Armani, A.; De Stefani, D.; Venditti, R.; Montefusco, S.; Scotto-Rosato, A.; Prezioso, C.; Forrester, A.; et al. Lysosomal calcium signalling regulates autophagy through calcineurin and TFEB. Nat. Cell Biol. 2015, 17, 288–299. [Google Scholar] [CrossRef]
  72. Morgan, A.J.; Davis, L.C.; Galione, A. Choreographing endo-lysosomal Ca2+ throughout the life of a phagosome. Biochim. Biophys. Acta. Mol. Cell Res. 2021, 1868, 119040. [Google Scholar] [CrossRef]
  73. Saran, S.; Azhar, M.; Manogaran, P.S.; Pande, G.; Nanjundiah, V. The level of sequestered calcium in vegetative amoebae of Dictyostelium discoideum can predict post-aggregative cell fate. Differentiation 1994, 57, 163–169. [Google Scholar] [CrossRef]
  74. Azhar, M.; Saran, S.; Nanjundiah, V. Spatial gradients of calcium in the slug of Dictyostelium discoideum. Curr. Sci. 1995, 68, 337–342. [Google Scholar]
  75. Azhar, M.; Manogaran, P.S.; Kennady, P.K.; Pande, G.; Nanjundiah, V. A Ca2+-dependent early functional heterogeneity in amoebae of Dictyostelium discoideum revealed by flow cytometry. Exp. Cell Res. 1996, 227, 344–351. [Google Scholar] [CrossRef] [PubMed]
  76. Azhar, M.; Kennady, P.K.; Pande, G.; Nanjundiah, V. Stimulation by DIF causes an increase of intracellular Ca2+ in Dictyostelium discoideum. Exp. Cell Res. 1997, 230, 403–406. [Google Scholar] [CrossRef] [PubMed]
  77. Aguilar, A. Polycystic kidney disease: Autophagy boost to treat ADPKD? Nat. Rev. Nephrol. 2017, 13, 134. [Google Scholar] [CrossRef] [PubMed]
  78. Criollo, A.; Altamirano, F.; Pedrozo, Z.; Schiattarella, G.G.; Li, D.L.; Rivera-Mejías, P.; Sotomayor-Flores, C.; Parra, V.; Villalobos, E.; Battiprolu, P.K.; et al. Polycystin-2-dependent control of cardiomyocyte autophagy. J. Mol. Cell Cardiol. 2018, 118, 110–121. [Google Scholar] [CrossRef] [PubMed]
  79. Pan, F.; Bu, L.; Wu, K.; Wang, A.; Xu, X. PKD2/Polycystin-2 inhibits LPS-induced acute lung injury in vitro and in vivo by activating autophagy. BMC Pulm. Med. 2023, 23, 171. [Google Scholar] [CrossRef] [PubMed]
  80. Peña-Oyarzun, D.; Troncoso, R.; Kretschmar, C.; Hernando, C.; Budini, M.; Morselli, E.; Lavandero, S.; Criollo, A. Hyperosmotic stress stimulates autophagy via Polycystin-2. Oncotarget 2017, 8, 55984–55997. [Google Scholar] [CrossRef] [PubMed]
  81. Lu, J.; Boheler, K.R.; Jiang, L.; Chan, C.W.; Tse, W.W.; Keung, W.; Ny Poon, E.; Li, R.A.; Yao, X. Polycystin-2 plays an essential role in glucose starvation-induced autophagy in human embryonic stem cell-derived cardiomyocytes. Stem Cells 2018, 36, 501–513. [Google Scholar] [CrossRef]
  82. Tresse, E.; Giusti, C.; Kosta, A.; Luciani, M.F.; Golstein, P. Autophagy and autophagic cell death in Dictyostelium. Methods Enzymol. 2008, 451, 343–358. [Google Scholar] [CrossRef]
  83. Calvo Garrido, J.; Carilla-Latorre, S.; Kubohara, Y.; Santos-Rodrigo, N.; Mesquita, A.; Soldati, T.; Golstein, P.; Escalante, R. Autophagy in Dictyostelium: Genes and pathways, cell death and infection. Autophagy 2010, 6, 686–701. [Google Scholar] [CrossRef]
  84. Swer, P.B.; Lohia, R.; Saran, S. Analysis of rapamycin-induced autophagy in Dictyostelium discoideum. Indian J. Exp. Biol. 2014, 52, 295–304. [Google Scholar] [PubMed]
  85. Swer, P.B.; Mishra, H.; Lohia, R.; Saran, S. Overexpression of TOR (target of rapamycin) inhibits cell proliferation in Dictyostelium discoideum. J. Basic Microbiol. 2016, 56, 510–519. [Google Scholar] [CrossRef] [PubMed]
  86. Jaiswal, P.; Majithia, A.R.; Rosel, D.; Liao, X.H.; Khurana, T.; Kimmel, A.R. Integrated actions of mTOR complexes 1 and 2 for growth and development of Dictyostelium. Int. J. Dev. Biol. 2019, 63, 521–527. [Google Scholar] [CrossRef]
  87. Gross, J.D.; Pears, C.J. Possible Involvement of the Nutrient and Energy Sensors mTORC1 and AMPK in Cell Fate Diversification in a Non-Metazoan Organism. Front. Cell Dev. Biol. 2021, 9, 758317. [Google Scholar] [CrossRef] [PubMed]
Cells 13 00610 g001
Figure 1. Developmental changes in pkd2 mRNA expression in Dictyostelium AX2 and AX4. (A) Relative pkd2 expression was measured by semiquantitative RT-PCR in AX2 over 24 h. pkd2 expression (cycle number) was normalized to abpC (filamin gene) expression. Cells were plated and allowed to develop on water agar, and every two hours cells were harvested and RNA was extracted. Data represent 2 separate experiments. Error bars are standard errors of the mean. (B) pkd2 mRNA expression over 24 h in AX4 developed on KK2 filter paper as measured using RNA-Seq by Parikh A et al. [47]. Image reproduced from data exported from dictyexpress.org [48,49]. To make the RNASeq and qRT-PCR measurements more directly comparable, the log2 of RPKM is plotted.
Figure 1. Developmental changes in pkd2 mRNA expression in Dictyostelium AX2 and AX4. (A) Relative pkd2 expression was measured by semiquantitative RT-PCR in AX2 over 24 h. pkd2 expression (cycle number) was normalized to abpC (filamin gene) expression. Cells were plated and allowed to develop on water agar, and every two hours cells were harvested and RNA was extracted. Data represent 2 separate experiments. Error bars are standard errors of the mean. (B) pkd2 mRNA expression over 24 h in AX4 developed on KK2 filter paper as measured using RNA-Seq by Parikh A et al. [47]. Image reproduced from data exported from dictyexpress.org [48,49]. To make the RNASeq and qRT-PCR measurements more directly comparable, the log2 of RPKM is plotted.
Cells 13 00610 g001
Cells 13 00610 g002
Figure 2. Expression of pkd2 was altered in the isolated transformants. pkd2 mRNA expression correlated with plasmid copy number. Individual dots represent the mean data for individual strains for 3 experiments. Expression levels were normalized against the abpC mRNA levels to adjust for loading and then measured relative to AX2 expression. The curve was fitted to a sigmoidal (hyperbolic tangent) function by the least-squares method and was highly significant (p = 1.22 × 10−8, F test). Antisense constructs are represented by negative copy numbers and overexpression constructs are represented by positive copy numbers; this convention has been described previously [38]. AX2 contains no construct so has a copy number of 0.
Figure 2. Expression of pkd2 was altered in the isolated transformants. pkd2 mRNA expression correlated with plasmid copy number. Individual dots represent the mean data for individual strains for 3 experiments. Expression levels were normalized against the abpC mRNA levels to adjust for loading and then measured relative to AX2 expression. The curve was fitted to a sigmoidal (hyperbolic tangent) function by the least-squares method and was highly significant (p = 1.22 × 10−8, F test). Antisense constructs are represented by negative copy numbers and overexpression constructs are represented by positive copy numbers; this convention has been described previously [38]. AX2 contains no construct so has a copy number of 0.
Cells 13 00610 g002
Cells 13 00610 g003
Figure 3. Cytoplasmic Ca2+ responses are larger in Polycystin-2-overexpressing strains and smaller in knockdown strains. Representative calcium responses in three strains, pkd2 KD strain HPF644 (copy number 13), control (HPF401) and pkd2 overexpression strain HPF839 (copy number 311). The top panel illustrates calcium reactions in vegetative cells when stimulated by folic acid, while the bottom panel depicts calcium responses in starved cells (7 h) stimulated with cAMP. Recordings commenced at 0 s, and the stimulus was administered within 1 s (highlighted by red arrows). The minor peak preceding the chemoattractant-induced calcium response results from the mechanical force of the stimulus injection and does not influence the magnitude of the chemoattractant response.
Figure 3. Cytoplasmic Ca2+ responses are larger in Polycystin-2-overexpressing strains and smaller in knockdown strains. Representative calcium responses in three strains, pkd2 KD strain HPF644 (copy number 13), control (HPF401) and pkd2 overexpression strain HPF839 (copy number 311). The top panel illustrates calcium reactions in vegetative cells when stimulated by folic acid, while the bottom panel depicts calcium responses in starved cells (7 h) stimulated with cAMP. Recordings commenced at 0 s, and the stimulus was administered within 1 s (highlighted by red arrows). The minor peak preceding the chemoattractant-induced calcium response results from the mechanical force of the stimulus injection and does not influence the magnitude of the chemoattractant response.
Cells 13 00610 g003
Cells 13 00610 g004
Figure 4. Calcium response magnitudes correlate with plasmid copy number. Cytosolic response magnitudes (Ca2+ nM) in strains with different copy numbers for pkd2 overexpression or KD constructs. Each point is the mean of 2–5 independent recordings for an individual strain. (A) Starved cells were stimulated with 1 µM cAMP. (B) Vegetative cells were stimulated with 1 µM folic acid, measured from real-time recordings. Response magnitudes positively correlate with the pkd2 expression index. Control strain HPF401 is indicated in red. Regression lines were fitted to a sigmoidal (hyperbolic tangent) function. The regressions were highly significant with the indicated probabilities (F test).
Figure 4. Calcium response magnitudes correlate with plasmid copy number. Cytosolic response magnitudes (Ca2+ nM) in strains with different copy numbers for pkd2 overexpression or KD constructs. Each point is the mean of 2–5 independent recordings for an individual strain. (A) Starved cells were stimulated with 1 µM cAMP. (B) Vegetative cells were stimulated with 1 µM folic acid, measured from real-time recordings. Response magnitudes positively correlate with the pkd2 expression index. Control strain HPF401 is indicated in red. Regression lines were fitted to a sigmoidal (hyperbolic tangent) function. The regressions were highly significant with the indicated probabilities (F test).
Cells 13 00610 g004
Cells 13 00610 g005
Figure 5. Kinetics of chemotactic Ca2+ responses in Polycystin-2 strains. (A) Negative relationship between maximum rise and fall rates in control, pkd2-overexpressing and knockdown (KD) strains. Each point represents an individual experiment. Blue squares indicate responses to 1 µM cAMP and red circles indicate responses to 1 µM folic acid. Aqua squares are means for cAMP responses and yellow circles are means for folic acid responses from left to right, KD, control and overexpression strains. Rise and fall rates at all stages in the responses were calculated from the Ca2+ concentrations at successive time points and the maximum rates of Ca2+ increase and decrease were then determined graphically using features of the R statistics and graphics package. Multiple regression analysis showed that neither the attractant (folate or cAMP) nor the strain type (overexpression or KD or control) made a difference in the regression relationship (p > 0.05). (B) Relationship between the response onset time and magnitude. The relationship is log-linear and negative for pkd2 overexpression, KD and control strains; however, each set of strains falls on a different line. Multiple regression analysis showed that the intercepts (significance probabilities shown) but not the slopes (p > 0.05) differed significantly from the line for the control strain.
Figure 5. Kinetics of chemotactic Ca2+ responses in Polycystin-2 strains. (A) Negative relationship between maximum rise and fall rates in control, pkd2-overexpressing and knockdown (KD) strains. Each point represents an individual experiment. Blue squares indicate responses to 1 µM cAMP and red circles indicate responses to 1 µM folic acid. Aqua squares are means for cAMP responses and yellow circles are means for folic acid responses from left to right, KD, control and overexpression strains. Rise and fall rates at all stages in the responses were calculated from the Ca2+ concentrations at successive time points and the maximum rates of Ca2+ increase and decrease were then determined graphically using features of the R statistics and graphics package. Multiple regression analysis showed that neither the attractant (folate or cAMP) nor the strain type (overexpression or KD or control) made a difference in the regression relationship (p > 0.05). (B) Relationship between the response onset time and magnitude. The relationship is log-linear and negative for pkd2 overexpression, KD and control strains; however, each set of strains falls on a different line. Multiple regression analysis showed that the intercepts (significance probabilities shown) but not the slopes (p > 0.05) differed significantly from the line for the control strain.
Cells 13 00610 g005
Cells 13 00610 g006
Figure 6. Basal cytosolic calcium concentration is reduced in pkd2 knockdown transformants. (A) Basal [Ca2+]c in cells starved and developed for 7 h in MES-DB. There was a significant difference in the basal cytosolic Ca2+ levels between the wild-type and KD strains (* p = 0.0116, ns = not significant), and the overexpression and KD strains (** p = 0.0031, One-Way ANOVA, with pairwise comparisons made by the Least-Squares Difference method). Error bars are standard errors of the mean. KD had six strains (n = 15), overexpression had eight strains (n = 19) and control had HPF401 one strain (n = 12). (B) Basal [Ca2+]c of vegetative cells growing in HL5 medium. The differences were not significant between wild-type and overexpression transformants, or wild-type and KD transformants. However, the difference between the overexpression and KD transformants was significant (* p = 0.0294, ns = not significant, One-Way ANOVA, with pairwise comparisons made by the Least-Squares Difference method). Error bars are standard errors of the mean. KD had six strains (n = 15), overexpression had eight strains (n = 18) and control had HPF401 one strain (n = 13).
Figure 6. Basal cytosolic calcium concentration is reduced in pkd2 knockdown transformants. (A) Basal [Ca2+]c in cells starved and developed for 7 h in MES-DB. There was a significant difference in the basal cytosolic Ca2+ levels between the wild-type and KD strains (* p = 0.0116, ns = not significant), and the overexpression and KD strains (** p = 0.0031, One-Way ANOVA, with pairwise comparisons made by the Least-Squares Difference method). Error bars are standard errors of the mean. KD had six strains (n = 15), overexpression had eight strains (n = 19) and control had HPF401 one strain (n = 12). (B) Basal [Ca2+]c of vegetative cells growing in HL5 medium. The differences were not significant between wild-type and overexpression transformants, or wild-type and KD transformants. However, the difference between the overexpression and KD transformants was significant (* p = 0.0294, ns = not significant, One-Way ANOVA, with pairwise comparisons made by the Least-Squares Difference method). Error bars are standard errors of the mean. KD had six strains (n = 15), overexpression had eight strains (n = 18) and control had HPF401 one strain (n = 13).
Cells 13 00610 g006
Cells 13 00610 g007
Figure 7. Altering Polycystin-2 expression affects differentiation and multicellular morphogenesis. Effects of Polycystin-2 expression levels on multicellular morphogenesis in Dictyostelium. Cells were grown on lawns of Enterobacter at 21 °C for ~24 h until mature fruiting bodies had formed. Photographs were captured using an Olympus SZ61 Moticam 2300 camera attached to a dissection microscope from above and from the side (Inserts). (A) Wildtype AX2. (B) Polycystin-2 KD strain HPF833 (copy number 22) exhibits very thin weak stalks, often unable to support the sorus. Insert (in red boxes) shows side-on image of typical long thin fragile stalks. (C) Overexpression strain HPF845 (copy number 149) has short thick stalks, suggesting increased stalk cell differentiation. Insert shows side view of typical fruiting bodies with short, thickened stalks. Scale bar = 1 mm.
Figure 7. Altering Polycystin-2 expression affects differentiation and multicellular morphogenesis. Effects of Polycystin-2 expression levels on multicellular morphogenesis in Dictyostelium. Cells were grown on lawns of Enterobacter at 21 °C for ~24 h until mature fruiting bodies had formed. Photographs were captured using an Olympus SZ61 Moticam 2300 camera attached to a dissection microscope from above and from the side (Inserts). (A) Wildtype AX2. (B) Polycystin-2 KD strain HPF833 (copy number 22) exhibits very thin weak stalks, often unable to support the sorus. Insert (in red boxes) shows side-on image of typical long thin fragile stalks. (C) Overexpression strain HPF845 (copy number 149) has short thick stalks, suggesting increased stalk cell differentiation. Insert shows side view of typical fruiting bodies with short, thickened stalks. Scale bar = 1 mm.
Cells 13 00610 g007
Cells 13 00610 g008
Figure 8. Polycystin-2 affects spore viability. Spores from three Polycystin-2 KD strains and three overexpression strains were harvested from fruiting bodies and heat activated. A known number of spores were then plated on lawns of Enterobacter and allowed to germinate. The viability was calculated by determining the number of germinated spores as a percentage of the number of plated spores. The means are calculated from pooled data from all strains within each group over three individual experiments. Error bars are standard errors of the mean. There was a significant difference in the viability between the KD strains and overexpression strains, KD n = 9, overexpression n = 9, control n = 3 (*** p = 0.0003, ns = not significant, Unpaired t-test).
Figure 8. Polycystin-2 affects spore viability. Spores from three Polycystin-2 KD strains and three overexpression strains were harvested from fruiting bodies and heat activated. A known number of spores were then plated on lawns of Enterobacter and allowed to germinate. The viability was calculated by determining the number of germinated spores as a percentage of the number of plated spores. The means are calculated from pooled data from all strains within each group over three individual experiments. Error bars are standard errors of the mean. There was a significant difference in the viability between the KD strains and overexpression strains, KD n = 9, overexpression n = 9, control n = 3 (*** p = 0.0003, ns = not significant, Unpaired t-test).
Cells 13 00610 g008
Cells 13 00610 g009
Figure 9. Polycystin-2 positively regulates pinocytosis and phagocytosis. (A) Pinocytosis was positively regulated by Polycystin-2. The consumption rate of FITC dextran-HL5 medium was measured in AX2 (red marker), Polycystin-2 KD and overexpression strains. The regression line was fitted by least squares to a linear function, and was significant, probability indicated (F test). (B) Phagocytosis was measured as consumption of E. coli expressing the red fluorescent protein DsRed. Phagocytosis and pinocytosis rates increased as Polycystin-2 expression increased, AX2 indicated in red. The regression line was fitted to a sigmoidal (hyperbolic tangent) function and was highly significant, probability indicated (F test).
Figure 9. Polycystin-2 positively regulates pinocytosis and phagocytosis. (A) Pinocytosis was positively regulated by Polycystin-2. The consumption rate of FITC dextran-HL5 medium was measured in AX2 (red marker), Polycystin-2 KD and overexpression strains. The regression line was fitted by least squares to a linear function, and was significant, probability indicated (F test). (B) Phagocytosis was measured as consumption of E. coli expressing the red fluorescent protein DsRed. Phagocytosis and pinocytosis rates increased as Polycystin-2 expression increased, AX2 indicated in red. The regression line was fitted to a sigmoidal (hyperbolic tangent) function and was highly significant, probability indicated (F test).
Cells 13 00610 g009
Cells 13 00610 g010
Figure 10. Polycystin-2 positively regulates Dictyostelium growth rates in HL5 medium and on lawns of E. coli. (A) Expression of Polycystin-2 is significantly correlated with generation times in liquid medium, longer generation times indicate slower growth. AX2 is indicated in red. Strains were grown exponentially in HL5 medium and shaken at 150 rpm, and generation times were determined by log-linear regression of the relationship between cell density and time. The regression line was fitted by least squares to a linear function. (B) Expression of Polycystin-2 is significantly correlated with growth rates on bacterial lawns. The growth velocity (rate of plaque expansion) was measured from linear regressions of the diameter of the plaques vs. time (h). AX2 is indicated in red. The regression line was fitted to a modified sigmoidal (modified hyperbolic tangent) function. The regressions were highly significant with the indicated probabilities (F test).
Figure 10. Polycystin-2 positively regulates Dictyostelium growth rates in HL5 medium and on lawns of E. coli. (A) Expression of Polycystin-2 is significantly correlated with generation times in liquid medium, longer generation times indicate slower growth. AX2 is indicated in red. Strains were grown exponentially in HL5 medium and shaken at 150 rpm, and generation times were determined by log-linear regression of the relationship between cell density and time. The regression line was fitted by least squares to a linear function. (B) Expression of Polycystin-2 is significantly correlated with growth rates on bacterial lawns. The growth velocity (rate of plaque expansion) was measured from linear regressions of the diameter of the plaques vs. time (h). AX2 is indicated in red. The regression line was fitted to a modified sigmoidal (modified hyperbolic tangent) function. The regressions were highly significant with the indicated probabilities (F test).
Cells 13 00610 g010
Cells 13 00610 g011
Figure 11. Polycystin-2 expression affects the mass or pH of acidic vesicles. LysoSensorTM Blue DND-167 was used to stain vegetative cells, and the increase in fluorescence was measured in a CLARIOstar plate reader. Fluorescence increased as Polycystin-2 expression increased, AX2 indicated in red. The regression line was fitted to a sigmoidal (hyperbolic tangent) function and was significant with the indicated probability (F test). Four overexpression, four KD strains and AX2 were tested in four independent experiments, and the data were normalized to AX2 within each experiment.
Figure 11. Polycystin-2 expression affects the mass or pH of acidic vesicles. LysoSensorTM Blue DND-167 was used to stain vegetative cells, and the increase in fluorescence was measured in a CLARIOstar plate reader. Fluorescence increased as Polycystin-2 expression increased, AX2 indicated in red. The regression line was fitted to a sigmoidal (hyperbolic tangent) function and was significant with the indicated probability (F test). Four overexpression, four KD strains and AX2 were tested in four independent experiments, and the data were normalized to AX2 within each experiment.
Cells 13 00610 g011
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Allan, C.Y.; Sanislav, O.; Fisher, P.R. Polycystin-2 Mediated Calcium Signalling in the Dictyostelium Model for Autosomal Dominant Polycystic Kidney Disease. Cells 2024, 13, 610. https://0-doi-org.brum.beds.ac.uk/10.3390/cells13070610

AMA Style

Allan CY, Sanislav O, Fisher PR. Polycystin-2 Mediated Calcium Signalling in the Dictyostelium Model for Autosomal Dominant Polycystic Kidney Disease. Cells. 2024; 13(7):610. https://0-doi-org.brum.beds.ac.uk/10.3390/cells13070610

Chicago/Turabian Style

Allan, Claire Y., Oana Sanislav, and Paul R. Fisher. 2024. "Polycystin-2 Mediated Calcium Signalling in the Dictyostelium Model for Autosomal Dominant Polycystic Kidney Disease" Cells 13, no. 7: 610. https://0-doi-org.brum.beds.ac.uk/10.3390/cells13070610

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop